JP3900001B2 - Building floor equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a floor apparatus for a building, for example, in a building such as a high-rise house or an office, in which a floor slab is placed and a floor board is disposed above the floor slab.
[0002]
[Prior art]
Conventionally, as a floor apparatus of this type, a plurality of large-drawing beams are arranged with only both ends thereof supported on the side wall of the building via elastic cushions and the like, and the middle part is completely floated, and There is provided a configuration in which a floor board is disposed on a large pull beam group through joists. According to the floor apparatus having such a configuration, it is supposed that a sound insulation effect can be expected by absorbing vibration applied to the floor board.
[0003]
[Problems to be solved by the invention]
However, according to the conventional floor apparatus described above, there is a possibility that the strength may be insufficient depending on the length of the pulling beam based on the scale.
[0004]
SUMMARY OF THE INVENTION An object of the present invention is to provide a building floor apparatus capable of reinforcing the strength by simplifying the structure and operation while maintaining the sound insulation effect.
[0005]
[Means for Solving the Problems]
  In order to achieve the above-described object, the building floor apparatus according to claim 1 of the present invention is provided with a plurality of large pull beams supported on the building side in at least two places, and these large pull beams and floor slabs are provided. In the meantime, a reinforcing beam is provided as an intersecting shape with respect to the large drawing beam, and this reinforcing beam extends continuously between the upper or lower portions of the plurality of large drawing beams.Supported on the floor slab side through the suspension means, and the reinforcing beam through the suspension memberIt is connected to the large draw beam side, and a floor board is disposed above the large draw beam.
[0006]
  Therefore, according to the invention of claim 1, it is possible to expect the sound insulation effect by absorbing the vibration applied to the floor board by the large drawing beam, and by supporting the plurality of large drawing beams by the common reinforcing beam, the large drawing beam Can strengthen the strength ofThe
[0007]
The building floor apparatus according to claim 2 of the present invention is characterized in that, in the configuration according to claim 1 described above, the overdrawing beam is connected by a reinforcing beam via a suspension member. .
[0008]
  Further, the reinforcing beam can be supported on the floor slab side through the suspension means. Moreover, by connecting the large pull beam to the reinforcing beam via the suspension member,The extension beam and floor slab can be easily extended continuously between the upper and lower portions of the multiple pull beams and the vertical height is adjusted according to the number and size of the suspension members used. It is possible to cope with a change in the height of the space formed between the two.
[0009]
  And of the present inventionClaim 2The building floor equipment described aboveClaim 1In the configuration, the coupling of the large beam and the reinforcing beam is performed using the space between the large beam and the floor slab and the upper and lower parts of the space below the large beam. Is.
[0010]
  ThereforeClaim 2According to the invention, the connecting portion can be formed in a compact manner, and the remaining space portion can be effectively used for storage, for example.
  Furthermore, the present inventionClaim 3The building floor apparatus is as claimed above.1 or 2In the described configuration, the large draw beam is received in a suspended posture on the floor slab side.
[0011]
  ThereforeClaim 3According to the invention, the load and vibration on the side of the large pull beam can be received on the floor slab side by the lifting force acting in the vertical direction.
  Moreover, the present inventionClaim 4The building floor equipment described aboveClaim 3In the configuration, the suspension means for receiving the large pull beam on the floor slab side in a suspended posture is configured such that the suspension position of the reinforcing beam is adjustable.
[0012]
  ThereforeClaim 4According to the invention, after the arrangement of the large beam and the floorboard, that is, the construction (arrangement) on the floor device side is all performed, the suspension position in the height direction of the reinforcing beam is adjusted by adjusting the suspension position by the suspension means. Make final adjustments.
[0013]
  The present inventionClaim 5The building floor equipment described aboveClaim 4In this configuration, the suspension means is characterized in that it is configured in a suspension posture that can be elastically deformed between a connection position on the reinforcing beam side and a support position on the floor slab side.
[0014]
  ThereforeClaim 5According to the invention, the load can be supported smoothly by elastic deformation of the suspension means, that is, “bending”.
  And of the present inventionClaim 6The building floor equipment described aboveClaim 3In the above configuration, the suspension means for receiving the large pull beam in the suspended posture on the floor slab side is configured to receive the reinforcing beam via the suspension wire.
[0015]
  ThereforeClaim 6According to the present invention, the large pull beam can be received in a suspended posture on the floor slab side by a simple configuration using a suspension wire.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Below, the 1st Embodiment in this invention is described based on FIGS.
[0017]
A high-rise house (an example of a building) 1 includes a floor slab 2 that forms a hierarchy, a side wall 3 of a compartment, and the like. ing. A plurality of large draw beams 5 are provided in parallel above the floor slab 2 and both ends of the large draw beams 5 are supported on the side wall 3 side.
[0018]
That is, the large pull beam 5 includes an intermediate vertical plate portion 5a, inclined plate portions 5b extending in the same direction on the left and right from the upper and lower ends of the vertical plate portion 5a, and upper and lower ends of the inclined plate portions 5b. A horizontal plate portion 5c extending in the horizontal direction in the same direction from left to right, and a short inclined plate portion 5d extending from the end of the horizontal plate portion 5c to the opposite side and toward the vertical plate portion 5a, and It is formed in a mold rail shape.
[0019]
Further, end through-holes 6 are formed in the upper horizontal plate portion 5c at both ends of the large pull beam 5, and at least one central portion (intermediate portion) (or a plurality of locations) and the vertical plate portion 5a. The intermediate part through-hole 7 which made two sets which set the predetermined space | interval in the length direction as 1 set is formed.
[0020]
In order to support both ends of the large beam 5 on the side wall 3, an angle-shaped beam receiving member 10 is disposed on the inner side surface of the side wall 3. The beam receiving member 10 has a horizontal plate portion disposed on a plurality of receiving members 11 via vibration-proof members (vibration-proof rubber) 12 and a vertical plate portion formed of a vibration-proof seal member (vibration-proof rubber). ) 13 is applied to the inner surface of the side wall 3 via 13. And the receiver 11 is being fixed to the side wall 3 via the connection tool 14 inserted in the side wall 3. As shown in FIG. Note that through holes 15 for connection are formed at predetermined plural positions in the horizontal plate portion of the beam receiving member 10.
[0021]
Accordingly, the horizontal plate portion 5c at the upper end of both ends of the draw beam 5 is brought into contact with the horizontal plate portion of the beam receiving member 10 from below, and is connected through the connected end through hole 6 and the connecting through hole 15. By operating a tool (bolt, nut, etc.) 16, both ends of the large pull beam 5 can be connected to the side wall 3.
[0022]
A reinforcing beam 17 is provided between the large drawing beam 5 group and the floor slab 2 so as to intersect the large drawing beam 5, and the reinforcing beam 17 is continuous between the plurality of large drawing beams 5. And is connected to the draw beam 5 side. Here, the large pull beam 5 is received in a suspended posture on the floor slab 2 side via the suspension means 20 and is connected to the reinforcing beam 17 via the suspension member 30.
[0023]
That is, the reinforcing beam 17 is formed of an angle-shaped mold rail, and long holes 18 for connection to the suspending means 20 and the suspending member 30 are formed at predetermined intervals at a plurality of predetermined positions in the horizontal plate portion.
[0024]
The suspension means 20 is configured so that the suspension position of the reinforcing beam 17 can be adjusted. That is, the main body 21 of the hanging means 20 includes a vertical plate portion 21a, an upper horizontal plate portion 21b extending in the horizontal direction from the upper and lower ends of the vertical plate portion 21a, and a lower horizontal plate portion 21c. Thus, it is formed in a C-shaped rail shape. A through hole 22 is formed in the upper horizontal plate portion 21b, and a long hole 23 in the width direction is formed in the lower horizontal plate portion 21c.
[0025]
Further, a turnbuckle (an example of a hanging position adjusting means) 25 is provided between the upper horizontal plate portion 21 b and the horizontal plate portion of the reinforcing beam 17. That is, the turnbuckle 25 has a rotation operation body 26 and a pair of upper and lower screw bodies 27A and 27B screwed to the rotation operation body 26, and the upper screw body 27A is formed on the upper horizontal plate portion 21b. The lower screw body 27B is passed through the through hole 22 and connected by the nut body 28A, and the lower screw body 27B is passed through the connecting long hole 18 formed in the horizontal plate portion of the reinforcing beam 17 and connected by the nut body 28B. The main body 21 is fixed so that its position can be adjusted in the width direction by an anchor bolt 29 or the like from the floor slab 2 side through a long hole 23 formed in the lower horizontal plate portion 21c.
[0026]
Therefore, the suspending means 20 is connected to the reinforcing beam 17 side via the lower screw body 27B and the nut body 28B, and further supported to the floor slab 2 side via the anchor bolt 29 and the like. The suspension means 20 has a main body 21 formed in a C-shaped rail shape, and the upper horizontal plate portion 21b and the lower horizontal plate portion 21c are connected and supported so that the connection position to the reinforcing beam 17 side is achieved. And a support position on the floor slab 2 side, the suspension posture is elastically deformable.
[0027]
The connection between the large pull beam 5 and the reinforcing beam 17 via the suspension member 30 uses the space between the large pull beam 5 and the floor slab 2 and the upper and lower portions of the space portion below the large pull beam 5. Has been done.
[0028]
That is, the suspension member 30 extends from the upper vertical plate portion 30a that can freely contact the vertical plate portion 5a of the large pull beam 5 from the outside, and extends downwardly from the lower end of the upper vertical plate portion 30a. An inclined plate portion 30b that can freely contact the lower inclined plate portion 5b from the outside, a lower vertical plate portion 30c that extends downward from the lower end of the inclined plate portion 30b, and a horizontal direction from the lower end of the lower vertical plate portion 30c. The horizontal plate portion 30d extends and can come into contact with the horizontal plate portion of the reinforcing beam 17 from above, and is formed in a mold shape.
[0029]
And, in the two places (one place or a plurality of places) in the width direction in the upper vertical plate portion 30a, long holes 31 in the width direction are respectively formed, and two places in the width direction in the horizontal plate portion 30d (one place or one place). Through holes 32 are respectively formed at a plurality of locations.
[0030]
Here, the long hole 31 communicates with the intermediate portion through hole 7 formed in the vertical plate portion 5a when the upper vertical plate portion 30a is brought into contact with the vertical plate portion 5a of the large pull beam 5 from the outside. The suspension member 30 is connected to the large pull beam 5 so that the position of the suspension member 30 can be adjusted by operating a connecting tool (bolt, nut, etc.) 33 between 31 and 7. Further, the through hole 32 communicates with the connecting long hole 18 formed in the horizontal plate portion of the reinforcing beam 17, so that a connecting tool (bolt, nut, etc.) 34 acts between the holes 32, 19. The suspension member 30 and the reinforcing beam 17 are coupled so that the position thereof can be freely adjusted.
[0031]
A plurality of joists 40 are disposed between the upper surfaces of the large beam 5, and a floor plate 41 is placed between the upper surfaces of the group of joists 40, so that the floor plate is located above the large beams 5. 41 is disposed. As a result, a storage space (space) S is formed between the upper surface 2 a of the floor slab 2 and the lower surface 41 a of the floor board 41.
[0032]
An entry / exit opening 42 is provided at an appropriate position of the floor plate 41, and the entry / exit opening 42 is formed by a rectangular cylindrical frame 43. The insertion / exit opening 42 is configured to be openable / closable by a lid body 44. At this time, the lid body 44 is pivotally connected to the rectangular cylindrical frame body 43 side via a hinge 45 at the other end. The side is configured to be in contact with a stopper body (not shown) provided on the rectangular tube frame 43 side.
[0033]
The operation in the first embodiment will be described below.
In configuring the floor apparatus, first, the large pull beam 5 is disposed at a predetermined plurality of locations. This is because a beam receiving member 10 is disposed via a vibration isolating member 12 on a plurality of receiving members 11 fixed to the side wall 3 via a connector 14, and then the horizontal plate portion of the beam receiving member 10. In the state where the horizontal plate portions 5c at the upper ends of both ends of the large pull beam 5 are brought into contact with each other from below, the connecting tool 16 is caused to act between the end through hole 6 and the connecting through hole 15 to thereby draw the large pull beam. This can be done by connecting both ends of 5 to the side wall 3.
[0034]
Then, an operation for supporting one (or a plurality of) reinforcing beams 17 on the floor slab 2 side via the suspension means 20 and an operation for connecting the large pull beam 5 to the reinforcement beam 17 side via the suspension member 30. In any order.
[0035]
That is, in the support operation through the suspension means 20, the main body 21 is first fixed to the floor slab 2 side through the long hole 23 and the anchor 29, and then the turnbuckle 25 is fixed to the upper horizontal plate portion 21 b of the main body 21. And the horizontal plate portion of the reinforcing beam 17 can be incorporated. At this time, the lower screw body 27B is displaced with respect to the connecting elongated hole 18 of the reinforcing beam 17 by using the connecting elongated hole 18 or via the elongated hole 23 with respect to the floor slab 2 side. Can be adjusted by moving.
[0036]
The connecting operation via the suspension member 30 is performed by first causing the upper vertical plate portion 30a of the suspension member 30 to act on the coupling tool 33 via the intermediate portion through hole 7 and the long hole 31 to The horizontal plate portion 5 a is connected to the vertical plate portion 5 a, and then the horizontal plate portion 30 d of the suspension member 30 is connected to the horizontal plate portion of the reinforcing beam 17 by acting the connecting tool 34 through the through hole 32 and the connecting long hole 18. It can be done.
[0037]
At this time, the displacement of the through hole 32 with respect to the connecting long hole 18 can be adjusted by moving the suspension member 30 toward the large pull beam 5 through the long hole 31. Further, the displacement in the vertical (height) direction of the reinforcing beam 17 with respect to the large pull beam 5 is adjusted by rotating the rotating operation body 26 of the turnbuckle 25 to raise and lower the connecting position of the lower screw body 27B. Can do.
[0038]
Thereafter, a plurality of joists 40 are disposed between the upper surfaces of the large pull beam 5, and the floor board 41 is placed between the upper surfaces of the joists 40 group, so that the floor slab 2 and the floor board 41 A storage space S may be formed between them to constitute a floor apparatus.
[0039]
After the arrangement of the large pull beam 5 and the floor board 41, that is, the configuration (arrangement) on the floor apparatus side is performed, the rotary operation body 26 of the turnbuckle 25 is rotated and operated in the height direction. The final adjustment can be performed, and the operation can be easily performed by entering the storage space S from the open / close opening 42.
[0040]
According to the floor apparatus configured in this way, a plurality of large beam 5 is supported on the side wall 3 through both ends thereof, so that vibration applied to the floor plate 41 is absorbed by the large beam 5 and a sound insulation effect is obtained. You can expect. Moreover, the strength of the large pull beam 5 can be reinforced by supporting the middle of the large pull beam 5 on the side of the reinforcing beam 17 by the suspension member 30, so that the reinforcing structure is based on the scale of the large pull beam 5. Regardless of the length, the operation can be simplified and employed.
[0041]
Further, the main body 21 of the suspending means 20 is formed in a C-shaped rail shape so that the suspension posture can be elastically deformed between the connection position on the reinforcing beam 17 side and the support position on the floor slab 2 side. Thus, the load can be smoothly supported by the elastic deformation, that is, “bending”. Note that by opening and closing the lid 44, articles can be taken in and out of the storage space S through the loading / unloading opening 42.
[0042]
Below, the 2nd Embodiment of this invention is described based on FIG. 6, FIG.
In the second embodiment, the suspension member 50 includes two (a plurality of) suspension bodies 51 and 55 that can be connected and separated, and is configured such that the vertical height can be adjusted according to the number of the suspension bodies 51 and 55 used. ing. Here, as the upper suspension body 51, the same suspension member 30 used in the above-described first embodiment is employed.
[0043]
In other words, the upper suspension body 51 extends from the lower end of the upper vertical plate portion 51a so as to freely contact the vertical plate portion 5a of the large pulling beam 5 from the outside, and extends downward from the lower end of the upper vertical plate portion 51a. An inclined plate portion 51b that can be in contact with the lower inclined plate portion 5b of the beam 5 from the outside, a lower vertical plate portion 51c that extends downward from the lower end of the inclined plate portion 51b, and a horizontal direction from the lower end of the lower vertical plate portion 51c. It consists of a horizontal plate portion 51d extending in the direction, and is formed into a mold shape.
[0044]
In addition, a long hole 52 in the width direction is formed in two places (one place or a plurality of places) in the width direction of the upper vertical plate portion 51a, respectively, and two places (one place or a plurality of places in the width direction in the horizontal plate portion 51d). The through-holes 53 are formed in the respective locations.
[0045]
Here, the long hole 52 communicates with the intermediate portion through-hole 7 formed in the vertical plate portion 5a when the upper vertical plate portion 51a is brought into contact with the vertical plate portion 5a of the large pull beam 5 from the outside. The suspension body 51 is connected to the large pull beam 5 so that the position of the suspension body 51 can be adjusted.
[0046]
The lower suspension body 55 includes a vertical plate portion 55a, and an upper horizontal plate portion 55b that extends in the horizontal direction from the upper end of the vertical plate portion 55a and that can freely contact the horizontal plate portion 51d of the upper suspension body 51 from below. The lower horizontal plate portion 55c extends in the horizontal direction from the lower end of the vertical plate portion 55a and can be brought into contact with the horizontal plate portion of the reinforcing beam 17 from above, and is formed into a mold shape.
[0047]
And the through hole 56 is formed in two places (one place or a plurality of places) in the width direction in the upper horizontal plate portion 55b, respectively, and two places (one place or a plurality of places) in the width direction in the lower horizontal plate portion 55c. The through-hole 57 is formed in.
[0048]
Here, the through hole 56 communicates with the through hole 53 formed in the horizontal plate portion 51d when the upper horizontal plate portion 55b is brought into contact with the horizontal plate portion 51d of the upper suspension body 51 from below, and thus the hole 56 is provided. , 53, the upper suspension body 51 and the lower suspension body 55 are coupled to each other by applying a coupling tool (bolt, nut, etc.) 58 between them. Further, the through hole 57 communicates with the connecting long hole 18 formed in the horizontal plate portion of the reinforcing beam 17, so that a connecting tool (bolt / nut etc.) 59 acts between the holes 57, 19. The lower suspension body 55 and the reinforcing beam 17 are connected.
[0049]
According to the second embodiment, the height change of the storage space S can be easily dealt with by adjusting the vertical height of the suspension member 50 by increasing or decreasing the number of the suspension bodies 51 and 55 used. obtain.
[0050]
Below, the 3rd Embodiment of this invention is described based on FIG.
That is, the large pull beam 5 is supported via the beam receiving member 60 on the upper surface side of the reverse beam portion 4A.
[0051]
According to the third embodiment, since the storage space S corresponds to the height of the reverse beam portion 4A, it can be formed using the dead space without increasing the occupied height of each floor.
[0052]
Below, the 4th Embodiment of this invention is described based on FIG.
That is, a plurality of receiving members 62 are provided on the inner surface of the side wall 3, and a beam receiving member 63 is provided between these receiving members 62. An end portion of the large pull beam 5 is supported on the beam receiving member 66.
[0053]
Below, the 5th Embodiment of this invention is described based on FIG.
That is, the suspension member 36 is connected to the lower surface of the large pull beam 5, and the suspension member 36 is constituted by a bracket 37 connected to the lower surface of the large pull beam 5, a vertical member 38 hanging from the bracket 37, and the like. The The reinforcing beam 17 is connected to the lower end of the vertical member 38. The suspension means 65 includes a frame-like body 66 in which the vertical member 38 is inserted and the reinforcing beam 17 is positioned, and a leg body 67 suspended from the lower surface of the frame-like body 66. Landed on the floor slab 2. The upper portion of the frame-like body 66 and the reinforcing beam 17 are connected by a suspension wire 68.
[0054]
According to the fifth embodiment, the large pull beam 5 is received in a suspended posture on the floor slab 2 side by a simple configuration using the suspension wire 68.
Below, the 6th Embodiment of this invention is described based on FIG. In the sixth embodiment, various shapes of the draw beam are shown.
[0055]
That is, the large drawing beam 70 shown in (a) includes an intermediate vertical plate portion 70a, an inclined plate portion 70b extending in a vertical direction from the upper and lower ends of the intermediate vertical plate portion 70a, and the inclined plates 70b. One side end vertical plate portion 70c extending vertically from both upper and lower ends of the portion 70b, a horizontal plate portion 70d extending horizontally from the upper and lower ends of the one side end vertical plate portion 70c in the left and right directions, and these horizontal plate portions 70d The other side end vertical plate portion 70e extending from the end of the other side and parallel to the one side end vertical plate portion 70c, and the side opposite to the end of the other side end vertical plate portion 70e and the intermediate It consists of a short inclined plate portion 70f extending toward the vertical plate portion 70a, and is formed in a mold rail shape.
[0056]
The large beam 71 shown in (b) includes an inclined plate portion 71a that is inclined up and down in the left-right direction, a horizontal plate portion 70b that extends in the left and right ends from the upper and lower ends of the inclined plate portion 71a, and these horizontal plate portions. It is composed of a short inclined plate portion 71c that extends from the end of 70b toward the inclined plate portion 71a, and is formed in a mold rail shape.
[0057]
The large drawing beam 72 shown in (c) includes a vertical plate portion 72a, an inclined plate portion 72b extending from the upper and lower ends of the vertical plate portion 72a in different directions on the left and right, and vertically inclined, and these inclined plate portions 72b. A horizontal plate portion 72c extending in the horizontal direction in the left and right opposite directions, and a short inclined plate portion 72d extending from the ends of the horizontal plate portion 72c opposite to each other and toward the vertical plate portion 72a. Therefore, it is formed in a mold rail shape.
[0058]
Furthermore, the large drawing beam 73 shown in (d) is composed of a pair of left and right vertical plate portions 73a and a pair of upper and lower horizontal plate portions 73b positioned between the upper and lower ends of these vertical plate portions 73a. It is formed in a cylindrical shape.
[0059]
The large beam 74 shown in (e) includes a pair of left and right vertical plate portions 74a, an inclined plate portion 74b extending from the upper and lower ends of the vertical plate portion 74a to the left and right outwards and inclined upward and downward, and these inclined portions. It consists of a pair of upper and lower horizontal plate portions 74c positioned between the upper end and the lower end of the plate portion 74b, and is formed in a cylindrical rail shape.
[0060]
As in the first to fourth embodiments described above, a plurality of large pull beams 5 supported on the building 1 side are provided in at least two places, and the large pull beams 5 and the floor slab 2 are large. A reinforcing beam 17 is provided as an intersecting shape with respect to the pulling beam 5, and the reinforcing beam 17 is continuously extended between upper and lower portions of the plurality of large pulling beams 5 and connected to the large pulling beam 5 side, According to the configuration in which the floor plate 41 is disposed above the large pull beam 5, vibrations applied to the floor plate 41 can be absorbed by the large pull beam 5 and a sound insulation effect can be expected, and a plurality of large pull beams 5 can be used as a common reinforcing beam. 17, it is possible to reinforce the strength of the large pull beam 5, so that the reinforcing structure can be reinforced regardless of the length based on the scale of the large pull beam 5, by reducing the number of connection points by the coupler, etc. Can be used with simple connection operations
[0061]
According to the configuration in which the large beam 5 is connected by the reinforcing beam 17 via the suspension member 30 as in the first and second embodiments described above, the space between the upper and lower portions of the multiple large beams 5 is reduced. The reinforcement beam 17 can be easily extended continuously, and the height formed by adjusting the vertical height according to the number and size of the suspension members 30 to be accommodated between the large pull beam 5 and the floor slab 2. It is possible to easily cope with a change in the height of the space (space) S.
[0062]
As in the first and second embodiments described above, the large beam 5 and the reinforcing beam 17 are connected to each other in the space between the large beam 5 and the floor slab 2 and below the large beam 5. According to the configuration performed using the upper and lower portions of the space portion, the connecting portion can be formed in a compact manner, and the remaining space portion can be effectively used for storage, for example.
[0063]
As in the first and second embodiments described above, according to the configuration in which the large draw beam 5 is received in a suspended posture on the floor slab 2 side, the load and vibration on the large draw beam 5 side are increased in the vertical direction. It can be reliably received on the floor slab 2 side by the acting lifting force.
[0064]
As in the first and second embodiments described above, the suspending means 20 for receiving the large pull beam 5 on the floor slab 2 side in a suspended posture is configured such that the suspending position of the reinforcing beam 17 can be adjusted. Thus, after all the arrangement of the large pull beam 5 and the floor board 41, that is, the configuration (arrangement) on the floor apparatus side is performed, the suspension position by the suspension means 20 is adjusted so that the height of the reinforcing beam 17 is increased. You can make final adjustments.
[0065]
As in the first and second embodiments described above, the suspension means 20 is configured in a suspension posture that can be elastically deformed between a connection position on the reinforcing beam 17 side and a support position on the floor slab 2 side. Thus, the load can be smoothly supported by the elastic deformation, that is, “bending”.
[0066]
In the above-described first to fourth embodiments, a form in which both ends of the draw beam 5 are supported on the building side is shown, but this is a form in which a plurality of places including the middle are supported on the building side. It may be.
[0067]
In each of the first and second embodiments described above, a form in which the reinforcing beam 17 is continuously extended between the lower portions of the plurality of large beams 5 is shown. It may be of a type extending continuously between the upper drawing beams 5.
[0069]
In the first and second embodiments described above, the connection between the large draw beam 5 and the reinforcing beam 17 is a space between the large draw beam 5 and the floor slab 2 and a space portion below the large draw beam 17. Although the form performed using the upper and lower portions of is shown, this may be a form in which connection is performed using the remaining space.
[0071]
In the first and second embodiments described above, there is shown a form in which the suspension means 20 for receiving the large pull beam 5 in the suspension posture on the floor slab 2 side is configured so that the suspension position of the reinforcing beam 17 can be adjusted. However, this may be of a type that employs fixed suspension means that cannot be adjusted.
[0072]
In the first and second embodiments described above, the suspension means 20 is configured in a suspension posture that can be elastically deformed between the connection position on the reinforcement beam 17 side and the support position on the floor slab 2 side. Although a form is shown, this may be a form that employs fixed suspension means that does not elastically deform.
[0073]
In each of the above-described embodiments, a bolt and nut type is shown as a connecting tool for each part, but this may be a rivet type depending on the location.
In the above-described fourth embodiment, the storage space S corresponding to the height of the reverse beam portion 4A is formed between the upper surface 2a of the floor slab 2 and the lower surface 41a of the floor plate 41. For example, in a building that is not a reverse beam as in the first to third embodiments, a configuration in which no storage space is formed may be used.
[0074]
In the first to third embodiments described above, a form in which the large pull beam 5 is supported between the side walls 3 is shown. This is because the large pull beam 5 is interposed between the side wall 3 and the reverse beam portion 4A. May be supported, or the extended beam 5 may be supported between the reverse beam portions 4A.
[0075]
In the first to third embodiments described above, a format in which articles can be stored in the storage space S is shown, but this is a format in which piping or wiring is performed in the storage space S, that is, using the space. It may be.
[0076]
【The invention's effect】
According to the first aspect of the present invention described above, the vibration applied to the floor board can be absorbed by the large drawing beam and a sound insulation effect can be expected, and the multiple large drawing beams are supported by the common reinforcing beam. The strength of the beam can be reinforced, and therefore, the reinforcing structure can be easily adopted regardless of the length based on the size of the extended beam.
[0077]
  AlsoThe reinforcing beam can be supported on the floor slab side through the suspension means. Moreover, by connecting the large pull beam to the reinforcing beam via the suspension member,Reinforcement beams can be easily extended continuously between the upper and lower portions of multiple large pull beams, and the vertical beam can be adjusted by adjusting the vertical height according to the number and size of suspension members used. Can easily cope with the height change of the space formed between the floor and the floor slab.
[0078]
  And the above-described present inventionClaim 2According to this, the connecting portion can be formed in a compact manner, and the remaining space portion can be effectively used for storage, for example.
  Further, according to the present invention described aboveClaim 3According to this, the load and vibration on the side of the large pull beam can be reliably received on the floor slab side by the lifting force acting in the vertical direction.
[0079]
  Moreover, the above-described present inventionClaim 4According to the above, after all the arrangement (arrangement) on the floor equipment side, such as the large beam and floorboard, is performed, the final adjustment in the height direction of the reinforcing beam is performed by adjusting the suspension position by the suspension means It can be performed.
[0080]
  In addition, the above-described present inventionClaim 5According to this, the load support can be smoothly performed by elastic deformation of the suspension means, that is, “bending”.
  And the above-described present inventionClaim 6According to the above, the large pull beam can be received in a suspended posture on the floor slab side by a simple configuration using a suspension wire.
[Brief description of the drawings]
FIG. 1 is a partially cutaway perspective view of a main part of a building floor apparatus according to a first embodiment of the present invention.
FIG. 2 is a longitudinal side view of the floor device of the same building.
FIG. 3 is a partially cutaway front view of the main part of the floor apparatus of the same building.
FIG. 4 is a longitudinal side view of a large beam support portion in the floor apparatus of the same building.
FIG. 5 is a longitudinal front view of the large beam support portion in the floor apparatus of the same building.
FIG. 6 shows a second embodiment of the present invention, and is a partially cutaway front view of a main part of a building floor apparatus.
FIG. 7 is a partially cutaway side view of the main part of the floor apparatus of the same building.
FIG. 8 shows a third embodiment of the present invention and is a schematic side view of a large pull beam support portion in a floor apparatus of a building.
FIG. 9 shows a fourth embodiment of the present invention and is a schematic side view of a large pull beam support portion in a building floor apparatus.
FIG. 10 shows a fifth embodiment of the present invention and is a longitudinal side view of a large pull beam support portion in a building floor apparatus.
FIGS. 11A and 11B are front views of various shapes of a large pull beam in a building floor apparatus according to a sixth embodiment of the present invention. FIGS.
[Explanation of symbols]
1 High-rise housing (building)
2 Floor slab
2a Top view
3 Side walls
4 Beam
5 Daiki Beam
6 End through hole
7 Middle part through hole
10 Beam receiving material
11 Receptacle
17 Reinforcement beam
18 Long hole for connection
20 Hanging means
21 Body
21a Vertical plate
21b Upper horizontal plate
21c Lower horizontal plate
22 Through hole
23 Long hole
25 Turnbuckle
26 Rotating operation body
27A Upper screw body
27B Lower screw body
30 Hanging members
31 long hole
32 Through hole
36 Hanging members
40 joist
41 Floor board
41a bottom surface
42 entrance
50 Hanging members
51 Top suspension
52 long hole
53 Through hole
55 Lower suspension
56 Through hole
57 Through hole
60 Beam receiving material
62 Receiver
63 Beam receiver
65 Lifting means
68 Hanging wire
70 Daiki Beam
71 Daiki Beam
72 Daiki Beam
73 Ohiki Beam
74 Daiki Beam
S Storage space (space)

Claims (6)

A plurality of large-drawn beams supported on the building side are provided in at least two locations, and a reinforcing beam is provided between the large-drawn beam and the floor slab as an intersection with the large-drawn beam. , Continuously extending between the upper and lower portions of the plurality of large beams , supported on the floor slab side through the suspension means, and the reinforcing beam connected to the large beam through the suspension members A floor apparatus for a building, wherein a floor board is disposed above the draw beam. 2. The connection between the large pull beam and the reinforcing beam is performed by using the space between the large pull beam and the floor slab and using the entire space above and below the large pull beam. Building floor equipment. 3. The building floor apparatus according to claim 1 , wherein the large pull beam is received in a suspended posture on the floor slab side . 4. The building floor apparatus according to claim 3 , wherein the suspension means for receiving the large pull beam on the floor slab side in a suspended posture is configured so that the suspension position of the reinforcing beam can be adjusted . Hanging Ri means includes a coupling position of the reinforcing beam side, between the support position by the floor slab side, building floor apparatus according to claim 4, characterized by being configured to elastically deformable suspension position . 4. The building floor apparatus according to claim 3 , wherein the suspension means for receiving the large pull beam on the floor slab side in a suspended posture is configured to receive the reinforcing beam via a suspension wire .

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